The LHCb VELO Upgrade

LHCb is a forward spectrometer experiment dedicated to the study of new physics in the decays of beauty and charm hadrons produced in proton collisions at the Large Hadron Collider (LHC) at CERN. The VErtex LOcator (VELO) is the microstrip silicon detector surrounding the interaction point, providing tracking and vertexing measurements. The upgrade of the LHCb experiment, planned for 2018, will increase the luminosity up to $\rm 2\times10^{33}\ cm^{-2}s^{-1}$ and will perform the readout as a trigger-less system with an event rate of 40 MHz. Extremely non-uniform radiation doses will reach up to $\rm 5 \times 10^{15}$ 1 MeV$\rm n_{eq}/cm^2$ in the innermost regions of the VELO sensors, and the output data bandwidth will be increased by a factor of 40. An upgraded detector is under development based in a pixel sensor of the Timepix/Medipix family, with 55 x 55 $\rm \mu m^2$ pixels. In addition a microstrip solution with finer pitch, higher granularity and thinner than the current detector is being developed in parallel. The current status of the VELO upgrade program will be described together with recent testbeam results.


The LHCb experiment
The LHCb [1] experiment is designed to exploit the enormous production cross sections of b and c hadrons in proton collisions at the LHC.It has demonstrated an excellent momentum resolution and particle identification capabilities, needed to study rare B decays.As the bb pairs are produced predominantly in the forward and backward directions the experiment was built to cover the pseudo-rapidity range of 1.9 < η < 4.9.
LHCb has been running from September 2009 and it has recorded 1.1 fb −1 pp collisions during 2011 and 2.1 fb −1 so far during 2012.Currently LHCb is running at a luminosity of L = 4 × 10 32 cm −2 s −1 with an average pile up of 1.4 interactions per bunch crossing (Fig. 1(a)).Both values are above design specifications which is an indication of the excellent performance of the experiment.

The VErtex LOcator (VELO)
The VErtex LOcator [2] is the silicon detector surrounding the LHCb interaction point.It is located only 7 mm from the beam axis during normal operation and measures very precisely the primary vertex and the decay vertices.It consists of two mobile detector halves with 21 modules each (Fig. 1(b)).Every module is composed of two n + -on-n 300 µm thick microstrip sensors, with a pitch range from 38 µm to 102 µm providing R and φ measurements.The 2048 channels of each sensor are readout at 1 MHz with 16 analogue front-end chips named Beetles [3].Each sensor has its own hybrid circuit, and it is glued onto a thermal pyrolytic graphite (TPG) foil which provides a thermal highway for the module.The TPG foil is coated with carbon fibre to give mechanical support to the module.The  As the sensors are placed so close, and perpendicular to 40 the beams, the radiation dose is highly non-uniform reaching 41 2.5 × 10 14 1 MeVn eq /cm 2 in the innermost regions.After al-42 most 3 years of operation, the VELO has already experienced 43 radiation damage [4].Leakage current has increased around

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The radiation dose will be extremely non-uniform as can be ap-66 preciated in Fig. 2(a).

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Luminosity by itself will not improve hadronic event yield  ing an output rate at the hottest chip > 12 Gbit/s.More detailed VeloPix specifications are given in Table 1, and a sketch of a 102 proposed pixel module is shown in Fig. 3(a).The list of requirements is not fully closed as we wish to get even closer to the beam, although it will increase considerably the readout rate.
And everything with the aim of achieving, if not improving, the excellent resolution and efficiency of the current VELO.

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cooling system is based on a bi-phase CO 2 plant which deliv-31 ers the coolant via stainless steel tubes to the cooling blocks 32 clamped to the base of the hybrids.33 The detector is placed inside the beam pipe and each half 34 is separated from the LHC beams by a vacuum box named RF-35 foil.The RF-foil is the corrugated AlMg3 foil of 300 µm that 36 is between the VELO sensors and beams.It encapsulates the 37 VELO modules in a secondary vacuum and shields the front 38 end electronics from the beams currents. 39

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µA per 100 pb −1 delivered, following the delivered lumi-45 nosity as expected.Type inversion has been measured in the 46 inner regions of the sensors, being the first sensors in LHC to 47 show it.More detailed information about radiation damage in 48 VELO can be found in [5].Despite the radiation damage no 49 significant performance degradation has been shown in the in-50 stalled VELO, providing a decay time resolution of ∼ 50 fs and 51 a point resolution of only 4 µm in the region of 40 µm pitch.52Moredetailed information about the VELO performance can 53 be found in[6].

54 2 .Figure 1 :or 5 ×
Figure 1: Fig. 1(a) compares average instantaneous luminosity in the LHCb experiment with the nominal value.Fig. 1(b) shows 3D representation of the current VELO detector

68Figure 2 :Fig. 2 (
Figure 2: Expected values of radiation and track rate per bunch crossing for the upgraded VELO.

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Strip modules.The future VELO could keep the same tracking 104 concept than the current, introducing improvements according 105 to the evolution of the silicon technologies.The higher lumi-106 nosity of the upgrade leads to increase occupancy.To deal with 107 the it the granularity will be improved by increasing the number 108 of strips, reducing the minimum pitch down to 30 µm, and vary-109 ing the pitch through the sensor to keep constant the occupancy 110 per strip.The planned sensors will be n-on-p type and 200 µm 111 thick.A new ASIC is under development exploiting synergies 112 with other silicon detectors in LHCb, which will provide func-113 tionality on chip like clustering, common mode suppression and 114 pedestal subtraction.The average rate per ASIC will be around 115 1.4 Gbits/s, and the data rate from the whole VELO will be 116 above 2 Tbit/s.117 R and φ prototypes were already produced (Fig. 3(b)) and 118 they will be tested in the coming testbeams.

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Mechanics and cooling 120 The RF-foil is the aluminium box which encloses the VELO 121 in a secondary vacuum.It allows overlap between the halves 122 of the detector and shields the front end electronics from the 123 RF noise pick-up and from beam currents.Depending on the 124 module technology, a custom RF-foil must be manufactured.A 125 new technique will be used, milling the 250 µm thick box from 126 a solid aluminium block by a 5-axis milling head.The milling 127 process is better than the pressing method used in the current 128 VELO because it can manufacture sharp corners needed for the 129 pixel option and allows a better thickness control.130A common feature in strip and pixel-based modules will be 131 the cooling spine.It will provide mechanical support but also 132 cooling up to the very end of the sensor in order to avoid ther-133 mal runaway due to the increased occupancy.To cool down the 134 cooling spine two main options are being developed, metallised 135 CVD diamond and microchannel.In the first case, thermal con-136 ductivity and mechanical needs are guaranteed by a diamond 137 spine clamped to a cooling block, while the IO signals of the 138 ASIC will be carried out by a thermally activated silver paste 139 deposited on the diamond (Fig. 4(a)).In the microchannel solu-140 tion ∼ 200×70 µm 2 channels are etched onto a silicon substrate, 141 where the CO 2 is forced to pass through [8, 9].The layout of 142 the channels can be adapted according to cooling needs.Sev-143 eral prototypes were already produced and tested in laboratory 144 environment (Fig. 4(b)).

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The upgraded VELO will be installed during the Long Shut-174 down 2, starting in 2018.A Letter of Intent[11], and a Frame-175 work Technical Design Report [12] were already published de-176 scribing the LHCb Upgrade.To be ready for the production 177 stage, an intense R&D program is underway providing useful 178 information to choose the most suitable technology on the dif-179 ferent aspects detailed previously.That decision will be made 180 in the second quarter of 2013, when the Technical Design Re-181 port will be published.

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The requirements for the LHCb VELO upgrade are very de-184 manding.The radiation dose will be increased by a factor ≥ 10 185 and the readout bandwidth will be increased by a factor of 40.186 R&D effort is underway working in parallel solutions: pixel and 187 strip based detector options are being developed, cooling solu-188 tions like metallised CVD diamond or microchannel are also 189 being investigated.To reduce the material budget in elements 190 placed in the acceptance (modules, RF-foil) is another of the 191 main concerns of the upgrade program.An intense testbeam 192 program is being carried out to study sensor technologies, radi-193 ation hardness, cooling schemes and readout electronics. 194